Class EmbeddedRungeKuttaIntegrator

  • All Implemented Interfaces:
    ButcherArrayProvider, ODEIntegrator
    Direct Known Subclasses:
    DormandPrince54Integrator, DormandPrince853Integrator, HighamHall54Integrator

    public abstract class EmbeddedRungeKuttaIntegrator
    extends AdaptiveStepsizeIntegrator
    implements ButcherArrayProvider
    This class implements the common part of all embedded Runge-Kutta integrators for Ordinary Differential Equations.

    These methods are embedded explicit Runge-Kutta methods with two sets of coefficients allowing to estimate the error, their Butcher arrays are as follows :

        0  |
       c2  | a21
       c3  | a31  a32
       ... |        ...
       cs  | as1  as2  ...  ass-1
           |--------------------------
           |  b1   b2  ...   bs-1  bs
           |  b'1  b'2 ...   b's-1 b's
     

    In fact, we rather use the array defined by ej = bj - b'j to compute directly the error rather than computing two estimates and then comparing them.

    Some methods are qualified as fsal (first same as last) methods. This means the last evaluation of the derivatives in one step is the same as the first in the next step. Then, this evaluation can be reused from one step to the next one and the cost of such a method is really s-1 evaluations despite the method still has s stages. This behaviour is true only for successful steps, if the step is rejected after the error estimation phase, no evaluation is saved. For an fsal method, we have cs = 1 and asi = bi for all i.

    • Constructor Detail

      • EmbeddedRungeKuttaIntegrator

        protected EmbeddedRungeKuttaIntegrator​(String name,
                                               int fsal,
                                               double minStep,
                                               double maxStep,
                                               double scalAbsoluteTolerance,
                                               double scalRelativeTolerance)
        Build a Runge-Kutta integrator with the given Butcher array.
        Parameters:
        name - name of the method
        fsal - index of the pre-computed derivative for fsal methods or -1 if method is not fsal
        minStep - minimal step (sign is irrelevant, regardless of integration direction, forward or backward), the last step can be smaller than this
        maxStep - maximal step (sign is irrelevant, regardless of integration direction, forward or backward), the last step can be smaller than this
        scalAbsoluteTolerance - allowed absolute error
        scalRelativeTolerance - allowed relative error
      • EmbeddedRungeKuttaIntegrator

        protected EmbeddedRungeKuttaIntegrator​(String name,
                                               int fsal,
                                               double minStep,
                                               double maxStep,
                                               double[] vecAbsoluteTolerance,
                                               double[] vecRelativeTolerance)
        Build a Runge-Kutta integrator with the given Butcher array.
        Parameters:
        name - name of the method
        fsal - index of the pre-computed derivative for fsal methods or -1 if method is not fsal
        minStep - minimal step (must be positive even for backward integration), the last step can be smaller than this
        maxStep - maximal step (must be positive even for backward integration)
        vecAbsoluteTolerance - allowed absolute error
        vecRelativeTolerance - allowed relative error
    • Method Detail

      • createInterpolator

        protected abstract org.hipparchus.ode.nonstiff.RungeKuttaStateInterpolator createInterpolator​(boolean forward,
                                                                                                      double[][] yDotK,
                                                                                                      ODEStateAndDerivative globalPreviousState,
                                                                                                      ODEStateAndDerivative globalCurrentState,
                                                                                                      EquationsMapper mapper)
        Create an interpolator.
        Parameters:
        forward - integration direction indicator
        yDotK - slopes at the intermediate points
        globalPreviousState - start of the global step
        globalCurrentState - end of the global step
        mapper - equations mapper for the all equations
        Returns:
        external weights for the high order method from Butcher array
      • getOrder

        public abstract int getOrder()
        Get the order of the method.
        Returns:
        order of the method
      • getSafety

        public double getSafety()
        Get the safety factor for stepsize control.
        Returns:
        safety factor
      • setSafety

        public void setSafety​(double safety)
        Set the safety factor for stepsize control.
        Parameters:
        safety - safety factor
      • getMinReduction

        public double getMinReduction()
        Get the minimal reduction factor for stepsize control.
        Returns:
        minimal reduction factor
      • setMinReduction

        public void setMinReduction​(double minReduction)
        Set the minimal reduction factor for stepsize control.
        Parameters:
        minReduction - minimal reduction factor
      • getMaxGrowth

        public double getMaxGrowth()
        Get the maximal growth factor for stepsize control.
        Returns:
        maximal growth factor
      • setMaxGrowth

        public void setMaxGrowth​(double maxGrowth)
        Set the maximal growth factor for stepsize control.
        Parameters:
        maxGrowth - maximal growth factor
      • estimateError

        protected abstract double estimateError​(double[][] yDotK,
                                                double[] y0,
                                                double[] y1,
                                                double h)
        Compute the error ratio.
        Parameters:
        yDotK - derivatives computed during the first stages
        y0 - estimate of the step at the start of the step
        y1 - estimate of the step at the end of the step
        h - current step
        Returns:
        error ratio, greater than 1 if step should be rejected